DE19828818A1 - Device and method for measuring exhaust gas components - Google Patents

Abstract

The invention relates to a device and a method for measuring exhaust gas components. Exhaust gas is supplied to at least one analyzer via a heated sample gas supply line. Due to the special arrangement of the pipe system as well as the main and sample conveying means, it is possible in a particularly simple way to determine measured values which ensure great reproducibility, whereby condensation of components in the exhaust gas is excluded.

Description

The invention relates to a device and a method for measuring Exhaust components according to the preambles of claims 1 and 13.

Devices and methods for measuring exhaust gas components from Internal combustion engines are well known. Raw exhaust gas or diluted exhaust gas, which is hereinafter referred to as measurement gas, one or fed to several analyzers to determine the concentration of Exhaust components such as CO, CO2, NO or hydrocarbons to eat. In order to calibrate the analyzers at regular intervals, So-called test / zero gases are used. The test / zero gases or that Sample gas is produced by a main conveyor in a main gas stream promoted. A sample gas stream is then via a branch point, ie is formed either by the sample gas or by the test / zero gas from Main gas stream branched off to the analyzer through a sample conveyor. The Changeover from sample gas to test / zero gas is carried out by a changeover valve.

When measuring internal combustion engine exhaust gases, the problem now arises that in particular all units of the device for measuring Exhaust components largely to environmental influences, such as Example temperature fluctuations, vibrations, etc. to be shielded in order to get the most accurate and reproducible measurement possible guarantee. Furthermore, the condensation of components in particular water, in the sample gas can be avoided, otherwise the Measurement result is falsified. To prevent condensation from forming, The sample gas must be heated accordingly. With the increased However, the temperature of the sample gas increases the design effort and thus  the costs for the piping system and the associated units, especially the changeover valve.

The invention is therefore based on the object, a device and a Methods of measuring exhaust components to create the measurement of hot or heated sample gas without the disadvantages mentioned above enables.

This object is achieved by the characterizing features of claims 1 and 13 solved.

A through the heated sample gas line section in the line system Condensation of, for example, water in the sample gas is prevented. The test / Zero gas contains no condensing components and therefore does not need to be heated to the extent of the sample gas. Because the test / Zero gas between the branch point to the bypass pump and the analyzer the changeover valve can be omitted, since when the test / Zero gas, the entire sample gas is passed through the main conveyor.

Preferably, the heated sample gas supply line has a filter element which in the Filtered out solid particles contained measuring gas.

In a special embodiment, one has been the main funding Bypass pump and a vacuum pump as a sample conveyor as advantageous proven. Through flow limiters in the sample gas, test / zero gas and Sample gas line section are the flow in a simple manner speeds and the pressures in the pipe system are regulated. The flow restrictors are advantageously in the form of a nozzle or capillary executed.

To compensate for pressure fluctuations through the targeted supply of ambient air same, the line system has a pressure regulator that is upstream  can be arranged by the bypass pump. To in particular the pressure in the To keep the sample line section constant, the pressure regulator is controlled by a Controlled pressure sensor, which is arranged in front of the analyzer.

For so-called "dead branches" in the test / zero gas line section and in To avoid pressure sensor line section, these line sections directly connected to the vacuum pump via flow limiters.

The analyzer advantageously has a reac for measuring nitrogen oxide tion chamber, which has a flow restrictor in a reac tion gas line section is connected to a reaction gas supply line.

In order to further increase the reproducibility of the measurement results, the Ein Reduce the flow of environmental parameters and at the same time fast on To generate response times of the analyzer, it is advantageous in the above ge called line system line system components, such as Lei tion sections, branch points, flow restrictors, sensors, etc. in / on to arrange a solid, block-shaped, thermally conductive element, the one Has heating element and a temperature sensor, and that at least one Coupling elements for the analyzer (s), the respective accessories ment and funding. Temperature fluctuations and vibration In this way, conditions can no longer influence the pipe system to take. It is also possible to set the temperature of the pipe system to one simple way to control what the reproducibility of the measurement results he increases. Furthermore, the assembly effort and thus the costs for the Pipe system reduced. Due to the short line sections, the Installation space of the piping system can be reduced and at the same time fast response times of the analyzer can be realized. For measuring nitrogen oxides can the reaction chamber in the massive, block-shaped, thermally conductive Be arranged element, the analyzer, for example, by a Flange connection can be connected directly to the reaction chamber.  

The invention is based on an embodiment shown in the drawing example explained in more detail.

Show it:

Fig. 1 is a flow chart for measuring sample gas components, and

Fig. 2 is a perspective view of the pipe system in the form of a block-shaped member,

Fig. 3 shows a detail view from FIG. 2.

Via a heated sample gas supply line 1 , sample gas for measuring the sample gas components is supplied to a line system 4 . The measuring gas also passes through a filter element 9 for filtering out particles. The exhaust gas is conveyed by a bypass pump 6 . Furthermore, the sample gas line section has a flow limiter 12 . At the branch point 5 , part of the sample gas flow is fed to an analyzer 3 as a sample gas by a vacuum pump 7 . Shortly before the analyzer, a further flow limiter 14 is arranged in a sample gas line section 11 .

In order to keep the pressure in the sample gas line section 11 constant, the pressure of the sample gas stream is supplied via a branch point 20 and a pressure sensor line section 17 to a pressure sensor 16 . This pressure sensor 16 is connected via an electronic control circuit to a pressure regulator 15 , which regulates the pressure in the main gas flow.

For calibration of the analyzer 3 to the analyzer, a test gas or zero gas must be supplied to 3 in particular Ab stands. This is done via the test / zero gas supply line 2 and the test / zero gas line section 10 . This line section also has a flow limiter 13 . The sample gas flowing through the sample gas supply line 1 does not reach the analyzer 3, provided the flow limiter is correctly designed. In this way, the changeover valve arranged in the known analysis devices can be dispensed with.

Under certain circumstances, the problem may arise that the pressure sensor line section 17 and the test / zero gas line section 10 have no gas flows, that is to say act like “dead branches”. The response times of the analyzer 3 can thereby be extended considerably. To prevent this, the line sections mentioned are connected directly to the vacuum pump via flow restrictors 18 and 19 . The result of this is that these line sections are flushed, that is to say continuously provided with a gas flow.

A reaction chamber 29 is also connected to the analyzer 3 for measuring nitrogen oxides. This reaction chamber 29 is connected via a flow limiter 22 , which is arranged in the reaction gas line section 21 , to a reaction gas supply line 23 , for example an ozonator.

Fig. 2 is now in the form shows the conduit system 4 of a block-shaped member 32. In the present exemplary embodiment, the block-shaped element 32 is a solid, heated and insulated metal block. For the sake of clarity, the representation is limited to the coupling elements and cutouts provided. The various components of the line system are connected to one another via lines in accordance with the flow diagram shown in FIG. 1. The routes can be easily z. B, manufacture by drilling or other manufacturing processes.

The block-shaped element 32 has cutouts into which a heating element 24 , a temperature sensor 25 and, for example, the capillaries 14 and 22 are to be inserted, which is shown in FIG. 3 as a cast-in capillary. Furthermore, FIG. 2 shows the reaction chamber 29 arranged in the line system 4 , to which the analyzer 3 is to be connected. The respective supply lines are to be connected via a measuring gas coupling element 26 , test / zero gas coupling element 27 , a reaction gas coupling element 28 and a pressure sensor coupling element 33 . The bypass pump 6 and the vacuum pump 7 are to be connected to the line system 4 via coupling elements 30 and 31, respectively.

The capillaries 14 , 22 can, for example, be cast in a spiral shape and then inserted as a cylindrical element in the recesses of the block-shaped element.

It is pointed out that the example shown represents only a special embodiment of the invention. For example, it is quite conceivable for a plurality of analyzers to be arranged in the line system 4 in the manner mentioned. Variants are also conceivable with regard to the arrangement of the flow restrictors and the pressure regulator. The block-shaped element 32 can also be used in conventional devices for measuring exhaust gas components, that is to say devices which have a changeover valve.

Claims (15)

1. Device for measuring exhaust gas components with

• - a sample gas feed line ( 1 ),
• - a test / zero gas supply line ( 2 ),
• - at least one analyzer ( 3 ),
• - A line system ( 4 ) for supplying a sample gas stream via a branch point ( 5 ) from the main gas stream to the analyzer ( 3 ), and
• - a main conveyor ( 6 ) and at least one sample conveyor ( 7 ),
  characterized in that
• - The sample gas supply line ( 1 ) is heated, and
• - The test / zero gas can be fed to a line section between the branch point ( 5 ) and the analyzer ( 3 ).

2. Device according to claim 1, characterized in that the Meßgaszulei device ( 1 ) has a filter element ( 9 ). 3. Apparatus according to claim 1 or 2, characterized in that the main conveyor ( 6 ) is a bypass pump. 4. Device according to one of the preceding claims, characterized in that the sample conveying means ( 7 ) is a vacuum pump. 5. Device according to one of the preceding claims, characterized in that a sample gas line section ( 8 ), a test / zero gas line section ( 10 ) and a sample gas line section ( 11 ) each have a Durchflußbe limiter ( 12 , 13 , 14 ). 6. The device according to claim 5, characterized in that the Durchflußbe limiters ( 12 , 13 , 14 ) are a nozzle or a capillary. 7. Device according to one of the preceding claims, characterized in that the line system ( 4 ) has a pressure regulator ( 15 ) which compensates for pressure fluctuations by targeted supply of ambient air. 8. The device according to claim 7, characterized in that a pressure sensor ( 16 ) is arranged in front of the analyzer, which controls the pressure regulator ( 15 ). 9. The device according to claim 8, characterized in that the test / zero gas line section ( 10 ) and a pressure sensor line section ( 17 ) directly via flow restrictors ( 18 , 19 ) with the vacuum pump ( 7 ) are connected. 10. Device according to one of the preceding claims, characterized in that upstream a reaction chamber ( 29 ) is connected to the analyzer, the line section via a flow limiter ( 22 ) in a reaction gas line ( 21 ) with a reaction gas supply line ( 23 ) is connected. 11. Line system for use in a device according to one of the preceding claims, characterized in that line system components, line sections, branch points, flow restrictors and sensors, etc. are arranged in a solid, block-shaped, thermally conductive element ( 32 ) which a heating element ( 24 ) and a temperature sensor ( 25 ), and which has at least one outer side coupling elements for the detector (s), the respective feed lines and conveying means. 12. Pipe system according to claim 11 in conjunction with claim 10, characterized in that the reaction chamber ( 29 ) is arranged in the solid block-shaped element ( 32 ). 13. A method for measuring exhaust gas components, at least one analyzer ( 3 ) being supplied with a sample gas stream via a branch point ( 5 ) of a line system ( 4 ), characterized in that

• - The sample gas in the sample gas feed line ( 1 ) is heated, and
• - For calibration purposes the analyzer ( 3 ) test / zero gas is supplied via a line section which is arranged between the branch point ( 5 ) and the analyzer ( 3 ).

14. The method according to claim 10, characterized in that the analyzer ( 3 ) is preceded by a pressure sensor ( 16 ) which controls a pressure regulator ( 15 ) by the pressure fluctuations in the line system ( 4 ) are compensated for by supplying ambient air. 15. The method according to claim 11 or 12, characterized in that a pressure sensor line section ( 17 ) and a test zero gas line section ( 10 ) via flow restrictors ( 18 , 19 ) are connected directly to a sample conveyor ( 7 ).